Preparation of Uranium/Plutonium Oxide Solid Solution Powder from Ammonium Uranyl–Plutonyl Carbonate in a Laboratory Microwave Unit

IF 0.9 Q4 CHEMISTRY, INORGANIC & NUCLEAR Radiochemistry Pub Date : 2024-04-23 DOI:10.1134/S1066362224010016

O. S. Dmitrieva, M. G. Dmitriev, A. Yu. Shadrin, D. A. Kapralov, A. S. Kornilov, A. A. Pylaeva, O. N. Nikitin

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Abstract

The method of fabrication of solid solution powder of uranium/plutonium (38%) oxides from the pulp of ammonium uranyl-plutonyl carbonate process (AUPuC) by microwave radiation in reducing and atmospheric environments was proposed and tested at the laboratory level. For research the pulp was prepared, obtained by co-precipitation of uranium and plutonium from nitrate solution (simulator for stripping product). The process consists of three main stages: oxidation of Pu(IV) to Pu(VI), precipitation, and conversion in a laboratory microwave unit. According to data of the X-ray diffraction analysis the powders synthesized in a reducing atmosphere and an atmospheric environment are a solid cubic solution (U_xPu_1–x)O₂ and (PuO₂, U₃O₈) mixed oxide, respectively. Scanning electron microscopy and electron probe microanalysis of the powder obtained in an atmospheric environment showed a fairly uniform distribution of U, Pu, and O in the solid phase.

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在实验室微波装置中利用铀-钚碳酸铵制备铀/钚氧化物固溶体粉末

摘要提出了在还原和大气环境中通过微波辐射从碳酸铀酰-钚铵工艺（AUPuC）浆料中制造铀/钚（38%）氧化物固溶体粉末的方法，并在实验室进行了测试。为进行研究，制备了铀和钚从硝酸盐溶液（剥离产品模拟器）中共沉淀得到的纸浆。该过程包括三个主要阶段：钚（IV）氧化成钚（VI）、沉淀和在实验室微波装置中进行转化。根据 X 射线衍射分析数据，在还原气氛和大气环境中合成的粉末分别是固体立方溶液 (UxPu1-x)O2 和 (PuO2, U3O8) 混合氧化物。在大气环境中获得的粉末的扫描电子显微镜和电子探针显微分析表明，U、Pu 和 O 在固相中的分布相当均匀。

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来源期刊

Radiochemistry CHEMISTRY, INORGANIC & NUCLEAR-

CiteScore

1.30

自引率

33.30%

发文量

期刊介绍： Radiochemistry is a journal that covers the theoretical and applied aspects of radiochemistry, including basic nuclear physical properties of radionuclides; chemistry of radioactive elements and their compounds; the occurrence and behavior of natural and artificial radionuclides in the environment; nuclear fuel cycle; radiochemical analysis methods and devices; production and isolation of radionuclides, synthesis of labeled compounds, new applications of radioactive tracers; radiochemical aspects of nuclear medicine; radiation chemistry and after-effects of nuclear transformations.